/**
 * Navit, a modular navigation system.
 * Copyright (C) 2005-2008 Navit Team
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * version 2 as published by the Free Software Foundation.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the
 * Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
 * Boston, MA  02110-1301, USA.
 */

#define _USE_MATH_DEFINES 1
#include <assert.h>
#include <stdio.h>
#include <math.h>
#include <limits.h>
#include <glib.h>
#include <string.h>
#include <stdlib.h>
#include "config.h"
#include "coord.h"
#include "debug.h"
#include "item.h"
#include "map.h"
#include "transform.h"
#include "projection.h"
#include "point.h"

/** @file
 *
 * Coordinate transformations and projections.
 */

/**
 * @brief Bitshift to apply during coordinate transformation.
 *
 * This bitshift is applied (left shift) during coordinate transformation (and later reversed).
 * The transformation is performed with integer arithmetic, and this shift reduces rounding
 * errors when converting floating point numbers to integers, particularly because some input
 * values are fairly small (for example, the entries in the transformation matrix, <tt>struct
 * transformation</tt>).
 *
 * This works because the transformations involve only multiplications, so the shift can be
 * applied to one factor and removed from the result.
 *
 * The value is a compromise; if it is too small, rounding errors increase, if it is too large,
 * signed integer calculations will overflow at high zoom levels (which is undefined behavior).
 *
 * @see transformation
 */
#define POST_SHIFT 5

/**
 * @brief The parameters needed to transform a map for display.
 */
struct transformation {
    int yaw;		/* Rotation angle */
    int pitch;
    int ddd;                /* 3d mode/isometric view active? (0/1) */
    int m00,m01,m02;	/* 3d transformation matrix */
    int m10,m11,m12;
    int m20,m21,m22;
    int xscale,yscale,wscale;
    int xscale3d,yscale3d,wscale3d;
#ifdef ENABLE_ROLL
    int roll;
    int hog;
#endif
    navit_float im00,im01,im02;	/* inverse 3d transformation matrix */
    navit_float im10,im11,im12;
    navit_float im20,im21,im22;
    struct map_selection *map_sel;
    struct map_selection *screen_sel;
    struct point screen_center;
    int screen_dist;
    int offx,offy,offz;
    int znear,zfar;
    struct coord map_center;	/* Center of source rectangle */
    enum projection pro;
    navit_float scale;		/* Scale factor */
    int scale_shift;
    int order;
    int order_base;
};

#ifdef ENABLE_ROLL
#define HOG(t) ((t).hog)
#else
#define HOG(t) 0
#endif

static void transform_set_screen_dist(struct transformation *t, int dist) {
    t->screen_dist=dist;
    t->xscale3d=dist;
    t->yscale3d=dist;
    t->wscale3d=dist << POST_SHIFT;
}

static void transform_setup_matrix(struct transformation *t) {
    navit_float det;
    navit_float fac;
    navit_float yawc=navit_cos(-M_PI*t->yaw/180);
    navit_float yaws=navit_sin(-M_PI*t->yaw/180);
    navit_float pitchc=navit_cos(-M_PI*t->pitch/180);
    navit_float pitchs=navit_sin(-M_PI*t->pitch/180);
#ifdef ENABLE_ROLL
    navit_float rollc=navit_cos(M_PI*t->roll/180);
    navit_float rolls=navit_sin(M_PI*t->roll/180);
#else
    navit_float rollc=1;
    navit_float rolls=0;
#endif

    int scale=t->scale;
    int order_dir=-1;

    dbg(lvl_debug,"yaw=%d pitch=%d center=0x%x,0x%x", t->yaw, t->pitch, t->map_center.x, t->map_center.y);
    t->znear=1 << POST_SHIFT;
    t->zfar=300*t->znear;
    t->scale_shift=0;
    t->order=t->order_base;
    if (t->scale >= 1) {
        scale=t->scale;
    } else {
        scale=1.0/t->scale;
        order_dir=1;
    }
    while (scale > 1) {
        if (order_dir < 0)
            t->scale_shift++;
        t->order+=order_dir;
        scale >>= 1;
    }
    fac=(1 << POST_SHIFT) * (1 << t->scale_shift) / t->scale;
    dbg(lvl_debug,"scale_shift=%d order=%d scale=%f fac=%f", t->scale_shift, t->order,t->scale,fac);

    t->m00=rollc*yawc*fac;
    t->m01=rollc*yaws*fac;
    t->m02=-rolls*fac;
    t->m10=(pitchs*rolls*yawc-pitchc*yaws)*(-fac);
    t->m11=(pitchs*rolls*yaws+pitchc*yawc)*(-fac);
    t->m12=pitchs*rollc*(-fac);
    t->m20=(pitchc*rolls*yawc+pitchs*yaws)*fac;
    t->m21=(pitchc*rolls*yaws-pitchs*yawc)*fac;
    t->m22=pitchc*rollc*fac;

    t->offx=t->screen_center.x;
    t->offy=t->screen_center.y;
    if (t->pitch) {
        t->ddd=1;
        t->offz=t->screen_dist;
        dbg(lvl_debug,"near %d far %d",t->znear,t->zfar);
        t->xscale=t->xscale3d;
        t->yscale=t->yscale3d;
        t->wscale=t->wscale3d;
    } else {
        t->ddd=0;
        t->offz=0;
        t->xscale=1;
        t->yscale=1;
        t->wscale=1;
    }
    det=(navit_float)t->m00*(navit_float)t->m11*(navit_float)t->m22+
        (navit_float)t->m01*(navit_float)t->m12*(navit_float)t->m20+
        (navit_float)t->m02*(navit_float)t->m10*(navit_float)t->m21-
        (navit_float)t->m02*(navit_float)t->m11*(navit_float)t->m20-
        (navit_float)t->m01*(navit_float)t->m10*(navit_float)t->m22-
        (navit_float)t->m00*(navit_float)t->m12*(navit_float)t->m21;

    t->im00=(t->m11*t->m22-t->m12*t->m21)/det;
    t->im01=(t->m02*t->m21-t->m01*t->m22)/det;
    t->im02=(t->m01*t->m12-t->m02*t->m11)/det;
    t->im10=(t->m12*t->m20-t->m10*t->m22)/det;
    t->im11=(t->m00*t->m22-t->m02*t->m20)/det;
    t->im12=(t->m02*t->m10-t->m00*t->m12)/det;
    t->im20=(t->m10*t->m21-t->m11*t->m20)/det;
    t->im21=(t->m01*t->m20-t->m00*t->m21)/det;
    t->im22=(t->m00*t->m11-t->m01*t->m10)/det;
}

struct transformation *
transform_new(struct pcoord *center, int scale, int yaw) {
    struct transformation *this_;

    this_=g_new0(struct transformation, 1);
    transform_set_screen_dist(this_, 100);
    this_->order_base=14;
    this_->pro=center->pro;
    this_->map_center.x=center->x;
    this_->map_center.y=center->y;
    this_->scale=scale/16.0;
    transform_set_yaw(this_, yaw);
    return this_;
}

int transform_get_hog(struct transformation *this_) {
    return HOG(*this_);
}

void transform_set_hog(struct transformation *this_, int hog) {
#ifdef ENABLE_ROLL
    this_->hog=hog;
#else
    dbg(lvl_error,"not supported");
#endif

}

int transform_get_attr(struct transformation *this_, enum attr_type type, struct attr *attr, struct attr_iter *iter) {
    switch (type) {
#ifdef ENABLE_ROLL
    case attr_hog:
        attr->u.num=this_->hog;
        break;
#endif
    default:
        return 0;
    }
    attr->type=type;
    return 1;
}

int transform_set_attr(struct transformation *this_, struct attr *attr) {
    switch (attr->type) {
#ifdef ENABLE_ROLL
    case attr_hog:
        this_->hog=attr->u.num;
        return 1;
#endif
    default:
        return 0;
    }
}

int transformation_get_order_base(struct transformation *this_) {
    return this_->order_base;
}

void transform_set_order_base(struct transformation *this_, int order_base) {
    this_->order_base=order_base;
}


struct transformation *
transform_dup(struct transformation *t) {
    struct transformation *ret=g_new0(struct transformation, 1);
    *ret=*t;
    ret->map_sel=map_selection_dup(t->map_sel);
    ret->screen_sel=map_selection_dup(t->screen_sel);
    return ret;
}

static const navit_float gar2geo_units = 360.0/(1<<24);
static const navit_float geo2gar_units = 1/(360.0/(1<<24));

void transform_to_geo(enum projection pro, struct coord *c, struct coord_geo *g) {
    int x,y,northern,zone;
    switch (pro) {
    case projection_mg:
        g->lng=c->x/6371000.0/M_PI*180;
        g->lat=navit_atan(exp(c->y/6371000.0))/M_PI*360-90;
        break;
    case projection_garmin:
        g->lng=c->x*gar2geo_units;
        g->lat=c->y*gar2geo_units;
        break;
    case projection_utm:
        x=c->x;
        y=c->y;
        northern=y >= 0;
        if (!northern) {
            y+=10000000;
        }
        zone=(x/1000000);
        x=x%1000000;
        transform_utm_to_geo(x, y, zone, northern, g);
        break;
    default:
        break;
    }
}

void transform_from_geo(enum projection pro, struct coord_geo *g, struct coord *c) {
    switch (pro) {
    case projection_mg:
        c->x=g->lng*6371000.0*M_PI/180;
        c->y=log(navit_tan(M_PI_4+g->lat*M_PI/360))*6371000.0;
        break;
    case projection_garmin:
        c->x=g->lng*geo2gar_units;
        c->y=g->lat*geo2gar_units;
        break;
    default:
        break;
    }
}

void transform_from_to_count(struct coord *cfrom, enum projection from, struct coord *cto, enum projection to,
                             int count) {
    struct coord_geo g;
    int i;

    for (i = 0 ; i < count ; i++) {
        transform_to_geo(from, cfrom, &g);
        transform_from_geo(to, &g, cto);
        cfrom++;
        cto++;
    }
}

void transform_from_to(struct coord *cfrom, enum projection from, struct coord *cto, enum projection to) {
    struct coord_geo g;
    transform_to_geo(from, cfrom, &g);
    transform_from_geo(to, &g, cto);
}


/**
 * @brief Transforms geodetic to Cartesian coordinates.
 *
 * This transforms geodetic coordinates (consisting of latitude and longitude) into ECEF Cartesian
 * coordinates.
 *
 * @param geo The WGS84 coordinates to convert
 * @param a Semi-minor axis of the ellipsoid
 * @param b Semi-minor axis of the ellipsoid
 * @param cart Points to a structure that will receive the Cartesian coordinates
 */
void transform_geo_to_cart(struct coord_geo *geo, navit_float a, navit_float b, struct coord_geo_cart *cart) {
    navit_float n,ee=1-b*b/(a*a);
    n = a/sqrtf(1-ee*navit_sin(geo->lat)*navit_sin(geo->lat));
    cart->x=n*navit_cos(geo->lat)*navit_cos(geo->lng);
    cart->y=n*navit_cos(geo->lat)*navit_sin(geo->lng);
    cart->z=n*(1-ee)*navit_sin(geo->lat);
}


/**
 * @brief Transforms Cartesian to geodetic coordinates.
 *
 * This transforms ECEF Cartesian coordinates into geodetic coordinates, consisting of latitude and
 * longitude.
 *
 * @param cart The Cartesian coordinates
 * @param a Semi-minor axis of the ellipsoid
 * @param b Semi-minor axis of the ellipsoid
 * @param geo Points to a structure that will receive the geodetic coordinates
 */
void transform_cart_to_geo(struct coord_geo_cart *cart, navit_float a, navit_float b, struct coord_geo *geo) {
    navit_float lat,lati,n,ee=1-b*b/(a*a), lng = navit_tan(cart->y/cart->x);

    lat = navit_tan(cart->z / navit_sqrt((cart->x * cart->x) + (cart->y * cart->y)));
    do {
        lati = lat;

        n = a / navit_sqrt(1-ee*navit_sin(lat)*navit_sin(lat));
        lat = navit_atan((cart->z + ee * n * navit_sin(lat)) / navit_sqrt(cart->x * cart->x + cart->y * cart->y));
    } while (fabs(lat - lati) >= 0.000000000000001);

    geo->lng=lng/M_PI*180;
    geo->lat=lat/M_PI*180;
}


/**
 * @brief Converts UTM coords to lat/long.
 *
 * Equations from USGS Bulletin 1532.
 *
 * @author Chuck Gantz- chuck.gantz@globalstar.com
 */
void transform_utm_to_geo(const double UTMEasting, const double UTMNorthing, int ZoneNumber, int NorthernHemisphere,
                          struct coord_geo *geo) {
//East Longitudes are positive, West longitudes are negative.
//North latitudes are positive, South latitudes are negative
//Lat and Long are in decimal degrees.

    double Lat, Long;
    double k0 = 0.99960000000000004;
    double a = 6378137;
    double eccSquared = 0.0066943799999999998;
    double eccPrimeSquared;
    double e1 = (1-sqrt(1-eccSquared))/(1+sqrt(1-eccSquared));
    double N1, T1, C1, R1, D, M;
    double LongOrigin;
    double mu, phi1Rad;
    double x, y;
    double rad2deg = 180/M_PI;

    x = UTMEasting - 500000.0; //remove 500,000 meter offset for longitude
    y = UTMNorthing;

    if (!NorthernHemisphere) {
        y -= 10000000.0;//remove 10,000,000 meter offset used for southern hemisphere
    }

    LongOrigin = (ZoneNumber - 1)*6 - 180 + 3;  //+3 puts origin in middle of zone

    eccPrimeSquared = (eccSquared)/(1-eccSquared);

    M = y / k0;
    mu = M/(a*(1-eccSquared/4-3*eccSquared*eccSquared/64-5*eccSquared*eccSquared*eccSquared/256));
    phi1Rad = mu	+ (3*e1/2-27*e1*e1*e1/32)*sin(2*mu)
              + (21*e1*e1/16-55*e1*e1*e1*e1/32)*sin(4*mu)
              +(151*e1*e1*e1/96)*sin(6*mu);

    N1 = a/sqrt(1-eccSquared*sin(phi1Rad)*sin(phi1Rad));
    T1 = tan(phi1Rad)*tan(phi1Rad);
    C1 = eccPrimeSquared*cos(phi1Rad)*cos(phi1Rad);
    R1 = a*(1-eccSquared)/pow(1-eccSquared*sin(phi1Rad)*sin(phi1Rad), 1.5);
    D = x/(N1*k0);

    Lat = phi1Rad - (N1*tan(phi1Rad)/R1)*(D*D/2-(5+3*T1+10*C1-4*C1*C1-9*eccPrimeSquared)*D*D*D*D/24
                                          +(61+90*T1+298*C1+45*T1*T1-252*eccPrimeSquared-3*C1*C1)*D*D*D*D*D*D/720);
    Lat = Lat * rad2deg;

    Long = (D-(1+2*T1+C1)*D*D*D/6+(5-2*C1+28*T1-3*C1*C1+8*eccPrimeSquared+24*T1*T1)
            *D*D*D*D*D/120)/cos(phi1Rad);
    Long = LongOrigin + Long * rad2deg;

    geo->lat=Lat;
    geo->lng=Long;
}

static struct coord transform_correct_projection(struct transformation *t, enum projection required_projection,
        struct coord c) {
    struct coord result;
    struct coord_geo g;
    if (required_projection == t->pro) {
        result=c;
    } else {
        transform_to_geo(required_projection, &c, &g);
        transform_from_geo(t->pro, &g, &result);
    }
    return result;
}

static struct coord transform_shift_by_center_and_scale(struct transformation *t, struct coord c) {
    struct coord result;
    result.x = c.x - t->map_center.x;
    result.y = c.y - t->map_center.y;
    result.x >>= t->scale_shift;
    result.y >>= t->scale_shift;
    return result;
}

struct coord_3d {
    int x;
    int y;
    int z;
};


static struct coord_3d transform_rotate(struct transformation *t, struct coord c) {
    struct coord_3d result;
    result.x=c.x*t->m00+c.y*t->m01+HOG(*t)*t->m02;
    result.y=c.x*t->m10+c.y*t->m11+HOG(*t)*t->m12;
    result.z=(c.x*t->m20+c.y*t->m21+HOG(*t)*t->m22);
    result.z+=t->offz << POST_SHIFT;
    dbg(lvl_debug, "result: (%d,%d,%d)", result.x,result.y,result.z);
    return result;
}

static struct coord_3d transform_z_clip(struct coord_3d c, struct coord_3d c_old, int zlimit) {
    struct coord_3d result;
    float clip_factor = ((float)zlimit-c.z)/(c_old.z-c.z);
    dbg(lvl_debug,"in (%d,%d,%d) - (%d,%d,%d)", c.x,c.y,c.z, c_old.x,c_old.y,c_old.z);
    result.x=c.x+(c_old.x-c.x)*clip_factor;
    result.y=c.y+(c_old.y-c.y)*clip_factor;
    result.z=zlimit;
    dbg(lvl_debug,"clip result: (%d,%d,%d)", result.x, result.y, result.z);
    return result;
}

static struct point transform_project_onto_view_plane(struct transformation *t, struct coord_3d c) {
    struct point result;
#if 0
    dbg(lvl_debug,"z=%d",c.z);
#endif
    result.x = (long long)c.x*t->xscale/c.z;
    result.y = (long long)c.y*t->yscale/c.z;
    return result;
}

static int transform_points_too_close(struct point screen_point, struct point screen_point_old, int mindist) {
    if (!mindist) {
        return 0;
    }
    // approximation of Euclidean distance
    return (abs(screen_point.x - screen_point_old.x) +
            abs(screen_point.y - screen_point_old.y)) < mindist;
}

struct z_clip_result {
    struct coord_3d clipped_coord;
    int visible;
    int process_coord_again;
    int skip_coord;
};

static struct z_clip_result transform_z_clip_if_necessary(struct coord_3d coord, int zlimit,
        struct z_clip_result clip_result_old) {
    int visibility_changed;
    struct z_clip_result clip_result= {{0,0}, 0, 0, 0};
    clip_result.visible=(coord.z < zlimit ? 0:1);
    visibility_changed=(clip_result_old.visible != -1)&&(clip_result.visible != clip_result_old.visible);
    if (visibility_changed) {
        clip_result.clipped_coord=transform_z_clip(coord, clip_result_old.clipped_coord, zlimit);
    } else {
        clip_result.clipped_coord=coord;
    }
    if (clip_result.visible && visibility_changed) {
        // line was clipped, but current point
        // is visible -> process it again
        clip_result.process_coord_again=1;
    } else if (!clip_result.visible && !visibility_changed) {
        clip_result.skip_coord=1;
    }
    return clip_result;
}

int transform(struct transformation *t, enum projection required_projection, struct coord *input,
              struct point *result, int count, int mindist, int width, int *width_result) {
    struct coord projected_coord, shifted_coord;
    struct coord_3d rotated_coord;
    struct point screen_point;
    int zlimit=t->znear;
    struct z_clip_result clip_result, clip_result_old= {{0,0}, -1, 0, 0};
    int i,result_idx = 0,result_idx_last=0;
    dbg(lvl_debug,"count=%d", count);
    for (i=0; i < count; i++) {
        dbg(lvl_debug, "input coord %d: (%d, %d)", i, input[i].x, input[i].y);
#if 0 /* doesn't work as wanted */
        if (i && input[i].x == input[0].x && input[i].y == input[0].y && result_idx && !width_result) {
            result[result_idx++]=result[0];
            continue;
        }
#endif
        projected_coord = transform_correct_projection(t, required_projection, input[i]);
        shifted_coord = transform_shift_by_center_and_scale(t, projected_coord);
        rotated_coord = transform_rotate(t, shifted_coord);

        if (t->ddd) {
            clip_result=transform_z_clip_if_necessary(rotated_coord, zlimit, clip_result_old);
            clip_result_old=clip_result;
            if(clip_result.process_coord_again) {
                i--;
            } else if (clip_result.skip_coord) {
                continue;
            }
#if 0
            clip_result.clipped_coord.z=2000000;
#endif
            screen_point = transform_project_onto_view_plane(t, clip_result.clipped_coord);
        } else {
            screen_point.x = rotated_coord.x>>POST_SHIFT;
            screen_point.y = rotated_coord.y>>POST_SHIFT;
        }
        screen_point.x+=t->offx;
        screen_point.y+=t->offy;
        dbg(lvl_debug,"result: (%d, %d)", screen_point.x, screen_point.y);

        if (i != 0 && i != count-1 &&
                (input[i+1].x != input[0].x || input[i+1].y != input[0].y)) {
            if (transform_points_too_close(screen_point, result[result_idx_last], mindist)) {
                continue;
            }
        }
        result[result_idx]=screen_point;
        if (width_result) {
            if (t->ddd) {
                dbg(lvl_debug,"width %d * %d / %d",width,t->wscale,clip_result.clipped_coord.z);
                width_result[result_idx]=width*t->wscale/clip_result.clipped_coord.z;
            } else
                width_result[result_idx]=width;
        }
        result_idx_last=result_idx;
        result_idx++;
    }
    return result_idx;
}

static void transform_apply_inverse_matrix(struct transformation *t, struct coord_geo_cart *in,
        struct coord_geo_cart *out) {
    out->x=in->x*t->im00+in->y*t->im01+in->z*t->im02;
    out->y=in->x*t->im10+in->y*t->im11+in->z*t->im12;
    out->z=in->x*t->im20+in->y*t->im21+in->z*t->im22;
}

static int transform_zplane_intersection(struct coord_geo_cart *p1, struct coord_geo_cart *p2, navit_float z,
        struct coord_geo_cart *result) {
    navit_float dividend=z-p1->z;
    navit_float divisor=p2->z-p1->z;
    navit_float q;
    if (!divisor) {
        if (dividend)
            return 0;	/* no intersection */
        else
            return 3;	/* identical planes */
    }
    q=dividend/divisor;
    result->x=p1->x+q*(p2->x-p1->x);
    result->y=p1->y+q*(p2->y-p1->y);
    result->z=z;
    if (q >= 0 && q <= 1)
        return 1;	/* intersection within [p1,p2] */
    return 2; /* intersection without [p1,p2] */
}

static void transform_screen_to_3d(struct transformation *t, struct point *p, navit_float z,
                                   struct coord_geo_cart *cg) {
    double xc,yc;
    double offz=t->offz << POST_SHIFT;
    xc=p->x - t->offx;
    yc=p->y - t->offy;
    cg->x=xc*z/t->xscale;
    cg->y=yc*z/t->yscale;
    cg->z=z-offz;
}

static int transform_reverse_near_far(struct transformation *t, struct point *p, struct coord *c, int near, int far) {
    double xc,yc;
    dbg(lvl_debug,"%d,%d",p->x,p->y);
    if (t->ddd) {
        struct coord_geo_cart nearc,farc,nears,fars,intersection;
        transform_screen_to_3d(t, p, near, &nearc);
        transform_screen_to_3d(t, p, far, &farc);
        transform_apply_inverse_matrix(t, &nearc, &nears);
        transform_apply_inverse_matrix(t, &farc, &fars);
        if (transform_zplane_intersection(&nears, &fars, HOG(*t), &intersection) != 1)
            return 0;
        xc=intersection.x;
        yc=intersection.y;
    } else {
        double xcn,ycn;
        xcn=p->x - t->offx;
        ycn=p->y - t->offy;
        xc=(xcn*t->im00+ycn*t->im01)*(1 << POST_SHIFT);
        yc=(xcn*t->im10+ycn*t->im11)*(1 << POST_SHIFT);
    }
    c->x=xc*(1 << t->scale_shift)+t->map_center.x;
    c->y=yc*(1 << t->scale_shift)+t->map_center.y;
    return 1;
}

int transform_reverse(struct transformation *t, struct point *p, struct coord *c) {
    return transform_reverse_near_far(t, p, c, t->znear, t->zfar);
}

double transform_pixels_to_map_distance(struct transformation *transformation, int pixels) {
    struct point line_in_map_center[2];
    struct coord c[2];
    struct point screen_center=transformation->screen_center;
    // Generally, the scale will not be the same across the map
    // (for example with Mercator projection), so calculate the
    // conversion in the screen center for a reasonable average value.
    line_in_map_center[0].x=screen_center.x-pixels/2;
    line_in_map_center[1].x=screen_center.x+pixels/2;
    line_in_map_center[0].y=screen_center.y;
    line_in_map_center[1].y=screen_center.y;
    transform_reverse(transformation, &line_in_map_center[0], &c[0]);
    transform_reverse(transformation, &line_in_map_center[1], &c[1]);
    return transform_distance(transform_get_projection(transformation), &c[0], &c[1]);
}

enum projection transform_get_projection(struct transformation *this_) {
    return this_->pro;
}

void transform_set_projection(struct transformation *this_, enum projection pro) {
    this_->pro=pro;
}

static int min4(int v1,int v2, int v3, int v4) {
    int res=v1;
    if (v2 < res)
        res=v2;
    if (v3 < res)
        res=v3;
    if (v4 < res)
        res=v4;
    return res;
}

static int max4(int v1,int v2, int v3, int v4) {
    int res=v1;
    if (v2 > res)
        res=v2;
    if (v3 > res)
        res=v3;
    if (v4 > res)
        res=v4;
    return res;
}

struct map_selection *
transform_get_selection(struct transformation *this_, enum projection pro, int order) {

    struct map_selection *ret,*curri,*curro;
    struct coord_geo g;

    ret=map_selection_dup(this_->map_sel);
    curri=this_->map_sel;
    curro=ret;
    while (curri) {
        if (this_->pro != pro) {
            transform_to_geo(this_->pro, &curri->u.c_rect.lu, &g);
            transform_from_geo(pro, &g, &curro->u.c_rect.lu);
            dbg(lvl_debug,"%f,%f", g.lat, g.lng);
            transform_to_geo(this_->pro, &curri->u.c_rect.rl, &g);
            transform_from_geo(pro, &g, &curro->u.c_rect.rl);
            dbg(lvl_debug,": - %f,%f", g.lat, g.lng);
        }
        dbg(lvl_debug,"transform rect for %d is %d,%d - %d,%d", pro, curro->u.c_rect.lu.x, curro->u.c_rect.lu.y,
            curro->u.c_rect.rl.x, curro->u.c_rect.rl.y);
        curro->order+=order;
#if 0
        curro->u.c_rect.lu.x-=500;
        curro->u.c_rect.lu.y+=500;
        curro->u.c_rect.rl.x+=500;
        curro->u.c_rect.rl.y-=500;
#endif
        curro->range=item_range_all;
        curri=curri->next;
        curro=curro->next;
    }
    return ret;
}

struct coord *
transform_center(struct transformation *this_) {
    return &this_->map_center;
}

struct coord *
transform_get_center(struct transformation *this_) {
    return &this_->map_center;
}

void transform_set_center(struct transformation *this_, struct coord *c) {
    this_->map_center=*c;
}


void transform_set_yaw(struct transformation *t,int yaw) {
    t->yaw=yaw;
    transform_setup_matrix(t);
}

int transform_get_yaw(struct transformation *this_) {
    return this_->yaw;
}

void transform_set_pitch(struct transformation *this_,int pitch) {
    this_->pitch=pitch;
    transform_setup_matrix(this_);
}
int transform_get_pitch(struct transformation *this_) {
    return this_->pitch;
}

void transform_set_roll(struct transformation *this_,int roll) {
#ifdef ENABLE_ROLL
    this_->roll=roll;
    transform_setup_matrix(this_);
#else
    dbg(lvl_error,"not supported");
#endif
}

int transform_get_roll(struct transformation *this_) {
#ifdef ENABLE_ROLL
    return this_->roll;
#else
    return 0;
#endif
}

void transform_set_distance(struct transformation *this_,int distance) {
    transform_set_screen_dist(this_, distance);
    transform_setup_matrix(this_);
}

int transform_get_distance(struct transformation *this_) {
    return this_->screen_dist;
}

void transform_set_scales(struct transformation *this_, int xscale, int yscale, int wscale) {
    this_->xscale3d=xscale;
    this_->yscale3d=yscale;
    this_->wscale3d=wscale;
}

void transform_set_screen_selection(struct transformation *t, struct map_selection *sel) {
    map_selection_destroy(t->screen_sel);
    t->screen_sel=map_selection_dup(sel);
    if (sel) {
        t->screen_center.x=(sel->u.p_rect.rl.x-sel->u.p_rect.lu.x)/2;
        t->screen_center.y=(sel->u.p_rect.rl.y-sel->u.p_rect.lu.y)/2;
        transform_setup_matrix(t);
    }
}

void transform_set_screen_center(struct transformation *t, struct point *p) {
    t->screen_center=*p;
}

void transform_get_size(struct transformation *t, int *width, int *height) {
    struct point_rect *r;
    if (t->screen_sel) {
        r=&t->screen_sel->u.p_rect;
        *width=r->rl.x-r->lu.x;
        *height=r->rl.y-r->lu.y;
    }
}

void transform_setup_source_rect(struct transformation *t) {
    int i;
    struct coord screen[4];
    struct point screen_pnt[4];
    struct point_rect *pr;
    struct map_selection *ms,*msm,*next,**msm_last;
    ms=t->map_sel;
    while (ms) {
        next=ms->next;
        g_free(ms);
        ms=next;
    }
    t->map_sel=NULL;
    msm_last=&t->map_sel;
    ms=t->screen_sel;
    while (ms) {
        msm=g_new0(struct map_selection, 1);
        *msm=*ms;
        pr=&ms->u.p_rect;
        screen_pnt[0].x=pr->lu.x;	/* left upper */
        screen_pnt[0].y=pr->lu.y;
        screen_pnt[1].x=pr->rl.x;	/* right upper */
        screen_pnt[1].y=pr->lu.y;
        screen_pnt[2].x=pr->rl.x;	/* right lower */
        screen_pnt[2].y=pr->rl.y;
        screen_pnt[3].x=pr->lu.x;	/* left lower */
        screen_pnt[3].y=pr->rl.y;
        if (t->ddd) {
            struct coord_geo_cart tmp,cg[8];
            struct coord c;
            int valid=0;
            unsigned char edgenodes[]= {
                0,1,
                1,2,
                2,3,
                3,0,
                4,5,
                5,6,
                6,7,
                7,4,
                0,4,
                1,5,
                2,6,
                3,7
            };
            for (i = 0 ; i < 8 ; i++) {
                transform_screen_to_3d(t, &screen_pnt[i%4], (i >= 4 ? t->zfar:t->znear), &tmp);
                transform_apply_inverse_matrix(t, &tmp, &cg[i]);
            }
            msm->u.c_rect.lu.x=0;
            msm->u.c_rect.lu.y=0;
            msm->u.c_rect.rl.x=0;
            msm->u.c_rect.rl.y=0;
            for (i = 0 ; i < 12 ; i++) {
                if (transform_zplane_intersection(&cg[edgenodes[i*2]], &cg[edgenodes[i*2+1]], HOG(*t), &tmp) == 1) {
                    c.x=tmp.x*(1 << t->scale_shift)+t->map_center.x;
                    c.y=tmp.y*(1 << t->scale_shift)+t->map_center.y;
                    dbg(lvl_debug,"intersection with edge %d at 0x%x,0x%x",i,c.x,c.y);
                    if (valid)
                        coord_rect_extend(&msm->u.c_rect, &c);
                    else {
                        msm->u.c_rect.lu=c;
                        msm->u.c_rect.rl=c;
                        valid=1;
                    }
                    dbg(lvl_debug,"rect 0x%x,0x%x - 0x%x,0x%x",msm->u.c_rect.lu.x,msm->u.c_rect.lu.y,msm->u.c_rect.rl.x,msm->u.c_rect.rl.y);
                }
            }
        } else {
            for (i = 0 ; i < 4 ; i++) {
                transform_reverse(t, &screen_pnt[i], &screen[i]);
                dbg(lvl_debug,"map(%d) %d,%d=0x%x,0x%x", i,screen_pnt[i].x, screen_pnt[i].y, screen[i].x, screen[i].y);
            }
            msm->u.c_rect.lu.x=min4(screen[0].x,screen[1].x,screen[2].x,screen[3].x);
            msm->u.c_rect.rl.x=max4(screen[0].x,screen[1].x,screen[2].x,screen[3].x);
            msm->u.c_rect.rl.y=min4(screen[0].y,screen[1].y,screen[2].y,screen[3].y);
            msm->u.c_rect.lu.y=max4(screen[0].y,screen[1].y,screen[2].y,screen[3].y);
        }
        dbg(lvl_debug,"%dx%d", msm->u.c_rect.rl.x-msm->u.c_rect.lu.x,
            msm->u.c_rect.lu.y-msm->u.c_rect.rl.y);
        *msm_last=msm;
        msm_last=&msm->next;
        ms=ms->next;
    }
}

long transform_get_scale(struct transformation *t) {
    return (int)(t->scale*16);
}

void transform_set_scale(struct transformation *t, long scale) {
    t->scale=scale/16.0;
    transform_setup_matrix(t);
}


int transform_get_order(struct transformation *t) {
    dbg(lvl_debug,"order %d", t->order);
    return t->order;
}



#define TWOPI (M_PI*2)
#define GC2RAD(c) ((c) * TWOPI/(1<<24))
#define minf(a,b) ((a) < (b) ? (a) : (b))

static double transform_distance_garmin(struct coord *c1, struct coord *c2) {
#ifdef USE_HALVESINE
    static const int earth_radius = 6371*1000; //m change accordingly
// static const int earth_radius  = 3960; //miles

//Point 1 cords
    navit_float lat1  = GC2RAD(c1->y);
    navit_float long1 = GC2RAD(c1->x);

//Point 2 cords
    navit_float lat2  = GC2RAD(c2->y);
    navit_float long2 = GC2RAD(c2->x);

//Haversine Formula
    navit_float dlong = long2-long1;
    navit_float dlat  = lat2-lat1;

    navit_float sinlat  = navit_sin(dlat/2);
    navit_float sinlong = navit_sin(dlong/2);

    navit_float a=(sinlat*sinlat)+navit_cos(lat1)*navit_cos(lat2)*(sinlong*sinlong);
    navit_float c=2*navit_asin(minf(1,navit_sqrt(a)));
#ifdef AVOID_FLOAT
    return round(earth_radius*c);
#else
    return earth_radius*c;
#endif
#else
#define GMETER 2.3887499999999999
    navit_float dx,dy;
    dx=c1->x-c2->x;
    dy=c1->y-c2->y;
    return navit_sqrt(dx*dx+dy*dy)*GMETER;
#undef GMETER
#endif
}

double transform_scale(int y) {
    struct coord c;
    struct coord_geo g;
    c.x=0;
    c.y=y;
    transform_to_geo(projection_mg, &c, &g);
    return 1/navit_cos(g.lat/180*M_PI);
}

#ifdef AVOID_FLOAT
static int
tab_sqrt[]= {14142,13379,12806,12364,12018,11741,11517,11333,11180,11051,10943,10850,10770,10701,10640,10587,10540,10499,10462,10429,10400,10373,10349,10327,10307,10289,10273,10257,10243,10231,10219,10208};

static int tab_int_step = 0x20000;
static int tab_int_scale[]= {10000,10002,10008,10019,10033,10052,10076,10103,10135,10171,10212,10257,10306,10359,10417,10479,10546,10617,10693,10773,10858,10947,11041,11140,11243,11352,11465,11582,11705,11833,11965,12103,12246,12394,12547,12706,12870,13039,13214,13395,13581,13773,13971,14174,14384,14600,14822,15050,15285,15526,15774,16028,16289,16557,16832,17114,17404,17700,18005,18316,18636,18964,19299,19643,19995,20355,20724,21102,21489,21885,22290,22705,23129,23563,24007,24461,24926,25401,25886,26383,26891};

int transform_int_scale(int y) {
    int i,size = sizeof(tab_int_scale)/sizeof(int);
    if (y < 0)
        y=-y;
    i=y/tab_int_step;
    if (i < size-1)
        return tab_int_scale[i]+((tab_int_scale[i+1]-tab_int_scale[i])*(y-i*tab_int_step))/tab_int_step;
    return tab_int_scale[size-1];
}
#endif

/**
 * @brief Calculates the distance between two points.
 *
 * @param pro The projection used for `c1` and `c2`.
 * @param c1 The first point.
 * @param c2 The second point.
 *
 * @return The distance in meters.
 */
double transform_distance(enum projection pro, struct coord *c1, struct coord *c2) {
    if (pro == projection_mg) {
#ifndef AVOID_FLOAT
        double dx,dy,scale=transform_scale((c1->y+c2->y)/2);
        dx=c1->x-c2->x;
        dy=c1->y-c2->y;
        return sqrt(dx*dx+dy*dy)/scale;
#else
        int dx,dy,f,scale=transform_int_scale((c1->y+c2->y)/2);
        dx=c1->x-c2->x;
        dy=c1->y-c2->y;
        if (dx < 0)
            dx=-dx;
        if (dy < 0)
            dy=-dy;
        while (dx > 20000 || dy > 20000) {
            dx/=10;
            dy/=10;
            scale/=10;
        }
        if (! dy)
            return dx*10000/scale;
        if (! dx)
            return dy*10000/scale;
        if (dx > dy) {
            f=dx*8/dy-8;
            if (f >= 32)
                return dx*10000/scale;
            return dx*tab_sqrt[f]/scale;
        } else {
            f=dy*8/dx-8;
            if (f >= 32)
                return dy*10000/scale;
            return dy*tab_sqrt[f]/scale;
        }
#endif
    } else if (pro == projection_garmin) {
        return transform_distance_garmin(c1, c2);
    } else {
        dbg(lvl_error,"Unknown projection: %d", pro);
        return 0;
    }
}

void transform_project(enum projection pro, struct coord *c, int distance, int angle, struct coord *res) {
    double scale;
    switch (pro) {
    case projection_mg:
        scale=transform_scale(c->y);
        res->x=c->x+distance*sin(angle*M_PI/180)*scale;
        res->y=c->y+distance*cos(angle*M_PI/180)*scale;
        break;
    default:
        dbg(lvl_error,"Unsupported projection: %d", pro);
        return;
    }

}


double transform_polyline_length(enum projection pro, struct coord *c, int count) {
    double ret=0;
    int i;

    for (i = 0 ; i < count-1 ; i++)
        ret+=transform_distance(pro, &c[i], &c[i+1]);
    return ret;
}

static int transform_overflow_possible_if_squared(int count, ...) {
    va_list ap;
    int i, value, result = 0;

    va_start (ap, count);
    for (i = 0; i < count; i++) {
        value = va_arg (ap, int);
        if (abs(value)>32767) {
            result = 1;
        }
    }
    va_end (ap);
    return result;
}

/**
 * @brief Determines the squared Mercator distance between two points.
 *
 * @param c0 The first coordinate
 * @param c1 The second coordinate
 *
 * @return The squared distance between `c1` and `c2`, or `INT_MAX` if an overflow occurs.
 */
int transform_distance_sq(struct coord *c1, struct coord *c2) {
    int dx=c1->x-c2->x;
    int dy=c1->y-c2->y;

    if (transform_overflow_possible_if_squared(2, dx, dy))
        return INT_MAX;
    else
        return dx*dx+dy*dy;
}

navit_float transform_distance_sq_float(struct coord *c1, struct coord *c2) {
    int dx=c1->x-c2->x;
    int dy=c1->y-c2->y;
    return (navit_float)dx*dx+dy*dy;
}

int transform_distance_sq_pc(struct pcoord *c1, struct pcoord *c2) {
    struct coord p1,p2;
    p1.x = c1->x;
    p1.y = c1->y;
    p2.x = c2->x;
    p2.y = c2->y;
    return transform_distance_sq(&p1, &p2);
}

/**
 * @brief Determines the point on a line segment that is closest to a reference point, and its distance
 * from the reference point.
 *
 * @param l0 The first coordinate of the line segment
 * @param l1 The second coordinate of the line segment
 * @param ref The reference point
 * @param lpnt Receives the coordinates of the point on the line segment that is closest to `ref`, can be `NULL`
 *
 * @return The square of the Mercator distance between `ref` and `lpnt`, or `INT_MAX` if an overflow occurred
 */
int transform_distance_line_sq(struct coord *l0, struct coord *l1, struct coord *ref, struct coord *lpnt) {
    int vx,vy,wx,wy;
    int c1,c2;
    int climit=1000000;
    struct coord l;

    vx=l1->x-l0->x;
    vy=l1->y-l0->y;
    wx=ref->x-l0->x;
    wy=ref->y-l0->y;

    if (transform_overflow_possible_if_squared(4, vx, vy, wx, wy)) {
        return INT_MAX;
    }

    c1=vx*wx+vy*wy;
    if ( c1 <= 0 ) {
        if (lpnt)
            *lpnt=*l0;
        return transform_distance_sq(l0, ref);
    }
    c2=vx*vx+vy*vy;
    if ( c2 <= c1 ) {
        if (lpnt)
            *lpnt=*l1;
        return transform_distance_sq(l1, ref);
    }
    while (c1 > climit || c2 > climit) {
        c1/=256;
        c2/=256;
    }
    l.x=l0->x+vx*c1/c2;
    l.y=l0->y+vy*c1/c2;
    if (lpnt)
        *lpnt=l;
    return transform_distance_sq(&l, ref);
}

navit_float transform_distance_line_sq_float(struct coord *l0, struct coord *l1, struct coord *ref,
        struct coord *lpnt) {
    navit_float vx,vy,wx,wy;
    navit_float c1,c2;
    struct coord l;

    vx=l1->x-l0->x;
    vy=l1->y-l0->y;
    wx=ref->x-l0->x;
    wy=ref->y-l0->y;

    c1=vx*wx+vy*wy;
    if ( c1 <= 0 ) {
        if (lpnt)
            *lpnt=*l0;
        return transform_distance_sq_float(l0, ref);
    }
    c2=vx*vx+vy*vy;
    if ( c2 <= c1 ) {
        if (lpnt)
            *lpnt=*l1;
        return transform_distance_sq_float(l1, ref);
    }
    l.x=l0->x+vx*c1/c2;
    l.y=l0->y+vy*c1/c2;
    if (lpnt)
        *lpnt=l;
    return transform_distance_sq_float(&l, ref);
}

/**
 * @brief Determines the point on a polyline that is closest to a reference point, and its distance
 * from the reference point.
 *
 * @param c An array containing the coordinates of the polyline
 * @param count Number of elements in `c`
 * @param ref The reference point
 * @param lpnt Receives the coordinates of the point on the polyline that is closest to `ref`, can be `NULL`
 * @param pos Receives the index of the line segment containing `lpnt`, can be NULL
 *
 * @return The square of the Mercator distance between `ref` and `lpnt`, or `INT_MAX` if an overflow occurred
 */
int transform_distance_polyline_sq(struct coord *c, int count, struct coord *ref, struct coord *lpnt, int *pos) {
    int i,dist,distn;
    struct coord lp;
    if (count < 2)
        return INT_MAX;
    if (pos)
        *pos=0;
    dist=transform_distance_line_sq(&c[0], &c[1], ref, lpnt);
    for (i=2 ; i < count ; i++) {
        distn=transform_distance_line_sq(&c[i-1], &c[i], ref, &lp);
        if (distn < dist) {
            dist=distn;
            if (lpnt)
                *lpnt=lp;
            if (pos)
                *pos=i-1;
        }
    }
    return dist;
}

int transform_douglas_peucker(struct coord *in, int count, int dist_sq, struct coord *out) {
    int ret=0;
    int i,d,dmax=0, idx=0;
    for (i = 1; i < count-2 ; i++) {
        d=transform_distance_line_sq(&in[0], &in[count-1], &in[i], NULL);
        if (d > dmax) {
            idx=i;
            dmax=d;
        }
    }
    if (dmax > dist_sq) {
        ret=transform_douglas_peucker(in, idx, dist_sq, out)-1;
        ret+=transform_douglas_peucker(in+idx, count-idx, dist_sq, out+ret);
    } else {
        if (count > 0)
            out[ret++]=in[0];
        if (count > 1)
            out[ret++]=in[count-1];
    }
    return ret;
}

int transform_douglas_peucker_float(struct coord *in, int count, navit_float dist_sq, struct coord *out) {
    int ret=0;
    int i,idx=0;
    navit_float d,dmax=0;
    for (i = 1; i < count-2 ; i++) {
        d=transform_distance_line_sq_float(&in[0], &in[count-1], &in[i], NULL);
        if (d > dmax) {
            idx=i;
            dmax=d;
        }
    }
    if (dmax > dist_sq) {
        ret=transform_douglas_peucker_float(in, idx, dist_sq, out)-1;
        ret+=transform_douglas_peucker_float(in+idx, count-idx, dist_sq, out+ret);
    } else {
        if (count > 0)
            out[ret++]=in[0];
        if (count > 1)
            out[ret++]=in[count-1];
    }
    return ret;
}


void transform_print_deg(double deg) {
    printf("%2.0f:%2.0f:%2.4f", floor(deg), fmod(deg*60,60), fmod(deg*3600,60));
}

#ifdef AVOID_FLOAT
static int tab_atan[]= {0,262,524,787,1051,1317,1584,1853,2126,2401,2679,2962,3249,3541,3839,4142,4452,4770,5095,5430,5774,6128,6494,6873,7265,7673,8098,8541,9004,9490,10000,10538};

static int atan2_int_lookup(int val) {
    int len=sizeof(tab_atan)/sizeof(int);
    int i=len/2;
    int p=i-1;
    for (;;) {
        i>>=1;
        if (val < tab_atan[p])
            p-=i;
        else if (val < tab_atan[p+1])
            return p+(p>>1);
        else
            p+=i;
    }
}

static int atan2_int(int dx, int dy) {
    int mul=1,add=0,ret;
    if (! dx) {
        return dy < 0 ? 180 : 0;
    }
    if (! dy) {
        return dx < 0 ? -90 : 90;
    }
    if (dx < 0) {
        dx=-dx;
        mul=-1;
    }
    if (dy < 0) {
        dy=-dy;
        add=180*mul;
        mul*=-1;
    }
    while (dx > 20000 || dy > 20000) {
        dx/=10;
        dy/=10;
    }
    if (dx > dy) {
        ret=90-atan2_int_lookup(dy*10000/dx);
    } else {
        ret=atan2_int_lookup(dx*10000/dy);
    }
    return ret*mul+add;
}
#endif

/**
 * @brief Gets the bearing from one point to another
 *
 * @param c1 The first coordinate
 * @param c2 The second coordinate
 * @param dir The direction: if it is -1, the bearing from c2 to c1 is returned, else the bearing from c1 to c2
 *
 * @return The bearing in degrees, {@code 0 <= result < 360}.
 */
int transform_get_angle_delta(struct coord *c1, struct coord *c2, int dir) {
    int dx=c2->x-c1->x;
    int dy=c2->y-c1->y;
#ifndef AVOID_FLOAT
    double angle;
    angle=atan2(dx,dy);
    angle*=180/M_PI;
#else
    int angle;
    angle=atan2_int(dx,dy);
#endif
    if (dir == -1)
        angle=angle-180;
    if (angle < 0)
        angle+=360;
    return angle;
}

int transform_within_border(struct transformation *this_, struct point *p, int border) {
    struct map_selection *ms=this_->screen_sel;
    while (ms) {
        struct point_rect *r=&ms->u.p_rect;
        if (p->x >= r->lu.x+border && p->x <= r->rl.x-border &&
                p->y >= r->lu.y+border && p->y <= r->rl.y-border)
            return 1;
        ms=ms->next;
    }
    return 0;
}

int transform_within_dist_point(struct coord *ref, struct coord *c, int dist) {
    if (c->x-dist > ref->x)
        return 0;
    if (c->x+dist < ref->x)
        return 0;
    if (c->y-dist > ref->y)
        return 0;
    if (c->y+dist < ref->y)
        return 0;
    if ((c->x-ref->x)*(c->x-ref->x) + (c->y-ref->y)*(c->y-ref->y) <= dist*dist)
        return 1;
    return 0;
}

int transform_within_dist_line(struct coord *ref, struct coord *c0, struct coord *c1, int dist) {
    int vx,vy,wx,wy;
    int n1,n2;
    struct coord lc;

    if (c0->x < c1->x) {
        if (c0->x-dist > ref->x)
            return 0;
        if (c1->x+dist < ref->x)
            return 0;
    } else {
        if (c1->x-dist > ref->x)
            return 0;
        if (c0->x+dist < ref->x)
            return 0;
    }
    if (c0->y < c1->y) {
        if (c0->y-dist > ref->y)
            return 0;
        if (c1->y+dist < ref->y)
            return 0;
    } else {
        if (c1->y-dist > ref->y)
            return 0;
        if (c0->y+dist < ref->y)
            return 0;
    }
    vx=c1->x-c0->x;
    vy=c1->y-c0->y;
    wx=ref->x-c0->x;
    wy=ref->y-c0->y;

    n1=vx*wx+vy*wy;
    if ( n1 <= 0 )
        return transform_within_dist_point(ref, c0, dist);
    n2=vx*vx+vy*vy;
    if ( n2 <= n1 )
        return transform_within_dist_point(ref, c1, dist);

    lc.x=c0->x+vx*n1/n2;
    lc.y=c0->y+vy*n1/n2;
    return transform_within_dist_point(ref, &lc, dist);
}

int transform_within_dist_polyline(struct coord *ref, struct coord *c, int count, int close, int dist) {
    int i;
    for (i = 0 ; i < count-1 ; i++) {
        if (transform_within_dist_line(ref,c+i,c+i+1,dist)) {
            return 1;
        }
    }
    if (close)
        return (transform_within_dist_line(ref,c,c+count-1,dist));
    return 0;
}

int transform_within_dist_polygon(struct coord *ref, struct coord *c, int count, int dist) {
    int i, j, ci = 0;
    for (i = 0, j = count-1; i < count; j = i++) {
        if ((((c[i].y <= ref->y) && ( ref->y < c[j].y )) ||
                ((c[j].y <= ref->y) && ( ref->y < c[i].y))) &&
                (ref->x < (c[j].x - c[i].x) * (ref->y - c[i].y) / (c[j].y - c[i].y) + c[i].x))
            ci = !ci;
    }
    if (! ci) {
        if (dist)
            return transform_within_dist_polyline(ref, c, count, dist, 1);
        else
            return 0;
    }
    return 1;
}

int transform_within_dist_item(struct coord *ref, enum item_type type, struct coord *c, int count, int dist) {
    if (type < type_line)
        return transform_within_dist_point(ref, c, dist);
    if (type < type_area)
        return transform_within_dist_polyline(ref, c, count, 0, dist);
    return transform_within_dist_polygon(ref, c, count, dist);
}

void transform_copy(struct transformation *src, struct transformation *dst) {
    memcpy(dst, src, sizeof(*src));
}

void transform_destroy(struct transformation *t) {
    map_selection_destroy(t->map_sel);
    map_selection_destroy(t->screen_sel);
    g_free(t);
}


/*
Note: there are many mathematically equivalent ways to express these formulas. As usual, not all of them are computationally equivalent.

L = latitude in radians (positive north)
Lo = longitude in radians (positive east)
E = easting (meters)
N = northing (meters)

For the sphere

E = r Lo
N = r ln [ tan (pi/4 + L/2) ]

where

r = radius of the sphere (meters)
ln() is the natural logarithm

For the ellipsoid

E = a Lo
N = a * ln ( tan (pi/4 + L/2) * ( (1 - e * sin (L)) / (1 + e * sin (L))) ** (e/2)  )


                                               e
                                               -
                   pi     L     1 - e sin(L)   2
    =  a ln( tan( ---- + ---) (--------------)   )
                   4      2     1 + e sin(L)


where

a = the length of the semi-major axis of the ellipsoid (meters)
e = the first eccentricity of the ellipsoid


*/


